Mercurial > repos > dereeper > sniplay
view VCF2Hapmap/VCF2FastaAndHapmap.pl @ 4:10627af23f10 draft
planemo upload
author | gandres |
---|---|
date | Tue, 15 Dec 2015 05:18:02 -0500 |
parents | 420b57c3c185 |
children |
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#!/usr/bin/perl use strict; use Getopt::Long; my $usage = qq~Usage:$0 <args> [<opts>] where <args> are: -v, --vcf <VCF input> -o, --out <Output basename> <opts> are: -r, --reference <Reference fasta file> -g, --gff <GFF input file to create alignments of genes> ~; $usage .= "\n"; my ($input,$out,$reference,$gff); GetOptions( "vcf=s" => \$input, "out=s" => \$out, "reference=s" => \$reference, "gff=s" => \$gff ); die $usage if ( !$input || !$out); if ($gff && !$reference) { die "You must provide a Fasta reference file when providing GFF annotation\n"; } my %ref_sequences; if ($reference) { my $id; my $sequence = ""; open(my $R,$reference) or die "cannot open file: $reference"; while(<$R>) { my $line =$_; $line =~s/\n//g; $line =~s/\r//g; if ($line =~ />([^\s]+)/){ $ref_sequences{$id} = $sequence; $id=$1;$sequence=""; } else { $sequence .= $line; } } close($R); $ref_sequences{$id} = $sequence; } my %chr_of_gene; my %ann; if ($gff) { open(my $G,$gff) or die "cannot open file: $gff"; while(<$G>) { my $line =$_; $line =~s/\n//g; $line =~s/\r//g; my @i = split(/\t/,$line); my $chr = $i[0]; my $feature = $i[2]; my $strand = $i[6]; my $start = $i[3]; my $stop = $i[4]; my $inf = $i[8]; if ($feature eq 'gene') { if ($inf =~/Name=([\w\-\.]+)[;\s]*/){$inf = $1;} $ann{$inf}{"start"}=$start; $ann{$inf}{"stop"}=$stop; $ann{$inf}{"strand"}=$strand; $chr_of_gene{$inf} = $chr; } } close($G); } my %IUPAC = ( '[A/G]'=> "R", '[G/A]'=> "R", '[C/T]'=> "Y", '[T/C]'=> "Y", '[T/G]'=> "K", '[G/T]'=> "K", '[C/G]'=> "S", '[G/C]'=> "S", '[A/T]'=> "W", '[T/A]'=> "W", '[A/C]'=> "M", '[C/A]'=> "M", '[C/A/T]'=> "H", '[A/T/C]'=> "H", '[A/C/T]'=> "H", '[C/T/A]'=> "H", '[T/C/A]'=> "H", '[T/A/C]'=> "H", '[C/A/G]'=> "V", '[A/G/C]'=> "V", '[A/C/G]'=> "V", '[C/G/A]'=> "V", '[G/C/A]'=> "V", '[G/A/C]'=> "V", '[C/T/G]'=> "B", '[T/G/C]'=> "B", '[T/C/G]'=> "B", '[C/G/T]'=> "B", '[G/C/T]'=> "B", '[G/T/C]'=> "B", '[T/A/G]'=> "D", '[A/G/T]'=> "D", '[A/T/G]'=> "D", '[T/G/A]'=> "D", '[G/T/A]'=> "D", '[G/A/T]'=> "D", ); my %snps_of_gene; my %snps_of_gene2; my %indiv_order; my $indiv_list; my %genotyping_infos; my $num_line = 0; my $genename_rank_in_snpeff = 4; my $find_annotations = `grep -c 'EFF=' $input`; open(my $HAPMAP,">$out.hapmap"); print $HAPMAP "rs# alleles chrom pos gene feature effect codon_change amino_acid_change MAF missing_data"; open(my $VCF,$input); while(<$VCF>) { my $line = $_; chomp($line); my @infos = split(/\t/,$line); if (/^##INFO=\<ID=EFF/ && /Amino_Acid_length \| Gene_Name \| Transcript_BioType \| Gene_Coding/) { $genename_rank_in_snpeff = 8; } if (scalar @infos > 9) { if (/#CHROM/) { for (my $j=9;$j<=$#infos;$j++) { my $individu = $infos[$j]; $indiv_list .= " $individu"; $indiv_order{$j} = $individu; } print $HAPMAP "$indiv_list\n"; } elsif (!/^#/) { $num_line++; my $chromosome = $infos[0]; my $chromosome_position = $infos[1]; my $ref_allele = $infos[3]; my $alt_allele = $infos[4]; if ($ref_allele =~/\w\w+/) { $ref_allele = "A"; $alt_allele = "T"; } elsif ($alt_allele =~/\w\w+/) { $ref_allele = "T"; $alt_allele = "A"; } my $info = $infos[7]; my $is_in_exon = "#"; my $is_synonyme = "#"; my $gene; if ($find_annotations > 1) { $gene = "intergenic"; } else { $gene = $chromosome; } my $modif_codon = "#"; my $modif_aa = "#"; my $geneposition; if ($info =~/EFF=(.*)/) { my @annotations = split(",",$1); foreach my $annotation(@annotations) { my ($syn, $additional) = split(/\(/,$annotation); if ($syn =~/STREAM/){next;} $is_in_exon = "exon"; if ($syn =~/UTR/) { $is_in_exon = $syn; } else { $is_synonyme = $syn; } my @infos_additional = split(/\|/,$additional); $gene = $infos_additional[$genename_rank_in_snpeff]; $modif_codon = $infos_additional[2]; $modif_aa = $infos_additional[3]; if ($syn =~/INTERGENIC/) { $is_synonyme = "#"; $gene = "intergenic"; $is_in_exon = "#"; } elsif ($syn =~/SYNONYM/) { $is_in_exon = "exon"; } elsif ($syn =~/INTRON/ or $syn =~/SPLICE_SITE_DONOR/) { $is_in_exon = "intron"; $is_synonyme = "#"; } if ($modif_aa =~/(\w)(\d+)$/) { $modif_aa = "$1/$1"; } elsif ($modif_aa =~/(\w)(\d+)(\w)/) { $modif_aa = "$1/$3"; } if ($infos_additional[8] =~/Exon/) { $is_in_exon = "exon"; } if (!$modif_aa){$modif_aa="#";} if (!$modif_codon){$modif_codon="#";} } } $gene =~s/\.\d//g; if ($ann{$gene}{"start"}) { my $strand = $ann{$gene}{"strand"}; if ($strand eq '-') { $geneposition = $ann{$gene}{"stop"} - $chromosome_position; } else { $geneposition = $chromosome_position - $ann{$gene}{"start"}; } } #if ($info =~/GenePos=(\d+);/) #{ # $geneposition = $1; #} my $ratio_missing_data; my $snp_frequency; my $genotyping = ""; if (2 > 1) { $genotyping_infos{"ref"} = "$ref_allele$ref_allele"; my %alleles_found; my $nb_readable_ind = 0; for (my $i = 9;$i <= $#infos;$i++) { my $dnasample = $indiv_order{$i}; my @infos_alleles = split(":",$infos[$i]); my $genotype = $infos_alleles[0]; $genotype =~s/0/$ref_allele/g; if ($alt_allele =~/,/) { my @alt_alleles = split(",",$alt_allele); my $num_all = 1; foreach my $alt_al(@alt_alleles) { $genotype =~s/$num_all/$alt_al/g; $num_all++; } } else { $genotype =~s/1/$alt_allele/g; } if ($genotype eq '.'){$genotype = "./.";} $genotype =~s/\./N/g; if ($genotype !~/N\/N/) { $nb_readable_ind++; } my @alleles; if ($genotype =~/\//) { @alleles = split(/\//,$genotype); } else { @alleles = split(/\|/,$genotype); } $genotyping .= join("",@alleles) . " "; $genotyping_infos{$dnasample} = join("",@alleles); foreach my $al(@alleles) { if ($al ne 'N'){$alleles_found{$al}++;} } } chop($genotyping); $snp_frequency = 0; my $max = 0; my $min = 10000000; my $total = 0; foreach my $al(keys(%alleles_found)) { my $nb = $alleles_found{$al}; $total+= $nb; if ($nb > $max) { $max = $nb; } if ($nb < $min) { $min = $nb; } } if ($total > 0) { $snp_frequency = sprintf("%.1f",($min/$total)*100); } $ratio_missing_data = 100 - ($nb_readable_ind / ($#infos - 8)) * 100; $ratio_missing_data = sprintf("%.1f",$ratio_missing_data); foreach my $dna(keys(%genotyping_infos)) { $snps_of_gene{$gene}{$geneposition}{$dna} = $genotyping_infos{$dna}; } } my $snp_type = "[$ref_allele/$alt_allele]"; $snps_of_gene2{$chromosome}{$chromosome_position} = $snp_type; #print $HAPMAP "$chromosome:$chromosome_position\t$snp_type\t$chromosome\t$chromosome_position\t$gene:$geneposition\t$is_in_exon\t$is_synonyme\t$modif_codon\t$modif_aa\t$snp_frequency%\t$nb_readable_ind\t$genotyping\n"; print $HAPMAP "$chromosome:$chromosome_position\t$ref_allele/$alt_allele\t$chromosome\t$chromosome_position\t$gene:$geneposition\t$is_in_exon\t$is_synonyme\t$modif_codon\t$modif_aa\t$snp_frequency%\t$ratio_missing_data%\t$genotyping\n"; } } } close($VCF); close($HAPMAP); if (!$reference){exit;} ################################################################# # generate flanking sequences for Illumina VeraCode technology ################################################################# open(my $FLANKING,">$out.flanking.txt"); foreach my $seq(keys(%ref_sequences)) { if ($snps_of_gene2{$seq}) { my $refhash = $snps_of_gene2{$seq}; my %hashreal = %$refhash; # create consensus my $refseq = $ref_sequences{$seq}; my $consensus = ""; my $previous = 0; foreach my $pos(sort {$a<=>$b} keys(%hashreal)) { my $length = $pos - $previous - 1; $consensus .= substr($refseq,$previous,$length); my $iupac_code = $IUPAC{$snps_of_gene2{$seq}{$pos}}; $consensus .= $iupac_code; $previous = $pos; } my $length = length($refseq) - $previous; $consensus .= substr($refseq,$previous,$length); foreach my $pos(sort {$a<=>$b} keys(%hashreal)) { my $snp_name = "$seq-$pos"; my $flanking_length = 60; my $length = $flanking_length; my $start = $pos - $flanking_length - 1; if ($pos <= $flanking_length) { $length = $pos - 1; $start = 0; } my $sequence = substr($consensus,$start,$length); $sequence .= $snps_of_gene2{$seq}{$pos}; $sequence .= substr($consensus,$pos,$flanking_length); print $FLANKING "$snp_name,$sequence,0,0,0,Project_name,0,diploid,Other,Forward\n"; } } } close($FLANKING); if (!$gff){exit;} my @individuals_list = split(/\t/,$indiv_list); if ((scalar @individuals_list * scalar keys(%snps_of_gene)) > 800000) { print "Sorry, too many sequences to manage ...\n"; exit; } open(my $ALIGN_EGGLIB,">$out.gene_alignment.fas"); my %alignments_ind; foreach my $seq(keys(%snps_of_gene)) { if ($snps_of_gene{$seq}) { my $refhash = $snps_of_gene{$seq}; my %hashreal = %$refhash; # get flanking sequences my %flanking5; my $start = $ann{$seq}{"start"}; my $stop = $ann{$seq}{"stop"}; my $strand = $ann{$seq}{"strand"}; my $genelength = $stop - $start+1; my $chr = $chr_of_gene{$seq}; my $refseq = substr($ref_sequences{$chr},$start-1,$genelength); if ($strand eq '-') { $refseq =~ tr /atcgATCG/tagcTAGC/; $refseq = reverse($refseq); } #print "$seq $chr $start $stop $refseq \n"; my $previous = 0; foreach my $pos(sort {$a<=>$b} keys(%hashreal)) { my $length = $pos - $previous - 1; $flanking5{$pos} = substr($refseq,$previous,$length); $previous = $pos; } my $length = length($refseq) - $previous; my $flanking3 = substr($refseq,$previous,$length); foreach my $ind(@individuals_list) { my $nb_missing_data_for_this_individual = 0; if ($ind) { my $alignment_for_ind = ""; my $seq_without_underscore = $seq; $seq_without_underscore =~s/_//g; $alignment_for_ind .= ">$seq_without_underscore" . "_$ind" . "_1\n"; foreach my $pos(sort {$a<=>$b} keys(%hashreal)) { $alignment_for_ind .= $flanking5{$pos}; my $geno = $snps_of_gene{$seq}{$pos}{$ind}; $geno =~s/N/?/g; if ($geno =~/\?/){$nb_missing_data_for_this_individual++;} my @alleles = split("",$geno); $alignment_for_ind .= $alleles[0]; if ($alleles[0] eq $alleles[1]) { $alignments_ind{$ind} .= $alleles[1]; } else { my $snp_type = "[" . $alleles[0] . "/" . $alleles[1] . "]"; $alignments_ind{$ind} .= $IUPAC{$snp_type}; } } $alignment_for_ind .= $flanking3; $alignment_for_ind .= "\n"; $alignment_for_ind .= ">$seq_without_underscore" . "_$ind" . "_2\n"; foreach my $pos(sort {$a<=>$b} keys(%hashreal)) { $alignment_for_ind .= $flanking5{$pos}; my $geno = $snps_of_gene{$seq}{$pos}{$ind}; $geno =~s/N/?/g; my @alleles = split("",$geno); $alignment_for_ind .= $alleles[1]; } $alignment_for_ind .= $flanking3; $alignment_for_ind .= "\n"; if (keys(%hashreal) != $nb_missing_data_for_this_individual) { print $ALIGN_EGGLIB $alignment_for_ind; } } } } } close($ALIGN_EGGLIB);